Forward Modeling Implementation of Rock Physics Models for Fractured Media
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Resource Overview
MATLAB-based implementation for forward modeling of rock physics in fractured media, featuring valuable algorithms and computational approaches for geological simulation
Detailed Documentation
This MATLAB-coded resource provides a comprehensive framework for forward modeling rock physics in fractured media, employing specialized algorithms to simulate complex geological structures. The implementation likely includes key functions for handling anisotropic elastic properties, fracture density calculations, and effective medium theory applications. Researchers can modify input parameters such as fracture orientation, aspect ratios, and background rock properties to analyze wave propagation characteristics and elastic moduli variations. The code probably utilizes matrix operations and tensor calculations to model seismic responses under different saturation conditions. This simulation capability is particularly valuable in petroleum engineering and geophysical exploration for predicting reservoir behavior, optimizing drilling strategies, and interpreting seismic data. The model's architecture may incorporate Hudson's fracture theory or Schoenberg's linear slip interface methods to represent fracture-induced anisotropy. By experimenting with different parameter combinations, users can gain insights into frequency-dependent attenuation, velocity dispersion, and fracture connectivity effects. This represents a significant computational tool for advancing fractured reservoir characterization studies.
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